Once fertilization has occurred, the egg begins to accumulate additional layers from the shell glands in the oviduct. In some species, this continues until a firm yet pliable leathery shell has been formed, permeable to both gases and liquids but capable of retaining much of its liquid content unless in a very dry place. The female then deposits the entire clutch of eggs in a protected damp, warm, and usually dark place, often along with clutches from other females of the same species, for the same stimuli that lead snakes to congregate for hibernation also take them to the same places for egg laying. Many species immediately abandon the eggs; some remain with the clutch and certainly appear to be protecting them from external danger; and a very few actually assume the role of a brood hen, maintaining a body temperature measurably higher than the surroundings and presumably assisting in incubation. In certain species, additional layers of membranous material are deposited around the embryo, but the calcareous (calcium-containing) shell does not form. Instead, the embryo is retained in the oviduct and continues its development there. This is termed ovoviviparous development, since it is simply an egg retained in the oviduct, in contrast to viviparous, the condition seen in mammals, where the fetus develops in the uterus and establishes a placental connection with the uterine wall to permit exchange of materials with the maternal circulation. But, while an umbilical connection does not develop, there is considerable evidence of an exchange of materials between mother and fetus across their contiguous, highly vascularized membranous surfaces.

Regardless of the devices used to provide it with protection, the snake fetus is always brought to term before the onslaught of environmental conditions that could result in its death. The embryonic turtle can sleep away its first winter in the egg and hatch the following spring none the worse for the experience, but there is as yet no evidence that snakes can do the same. The contrast may result from the fact that the female turtle can scoop out a hole deep enough for freezing temperatures not to affect her brood, but the female snake is restricted, both by her limblessness and by the nature of the egg itself, to egg laying on or near the surface, where below-freezing temperatures are unavoidable. In the tropics, evidence is scanty, but it would appear that there is an endogenous (i.e., controlled from within) rhythm there as well, since young are not produced throughout the year.

Early development and growth

The young snake, whether from an egg or born alive, comes equipped with a sharp cutting device on its upper lip, the egg tooth. It slashes its way out of the rubbery eggshell with this tooth or, in the case of the live-born, cuts its way out of the soft membranes and is instantly competent to cope with its surroundings. Almost invariably, the first act of a newborn snake is to extend its tongue and taste the surroundings, conveying to the Jacobson’s organ (a sensitive region in the roof of the mouth) chemical information perhaps more significant than the visual cues picked up by the pair of very inexperienced eyes. Young snakes begin to feed immediately after hatching, displaying considerable ability in the capture and consumption of prey. Venomous snakes are born with functional venom glands and fangs and are capable of immediate utilization of their most formidable weapons. Some of the viperid snakes are born with a bright green tail tip (contrasting strongly with the rest of the body colour), which they are capable of waving and shaking in a way that attracts the attention of possible prey. Within a very short time after birth, the first sloughing of the skin takes place, and the egg tooth is shed at about the same time.

The rate of growth is correlated with availability of food and temperatures high enough to permit full metabolic activity. When all factors are optimal, snakes grow surprisingly fast. A brood of California rosy boas (Charina trivirgata) doubled their length in a nine-month period, growing to only a few inches shorter than their mother, an adult close to maximum length for the species. It has been suggested that all snakes grow rapidly until they reach sexual maturity, after which time growth slows but very seldom stops completely. Snakes have indeterminate growth, which means there is no terminal point in time or size for growth in their lifetime, but they can continue to increase in length until they die. Sexual maturity is reached in about two years by many snakes. In the larger species, sexual maturity comes later, after four or five years or more.

In terms of total length, the reticulated pythons (Python reticulatus)—which inhabit Southeast Asia, Indonesia, and the Philippines—are the largest, growing to more than 7 metres (23 feet) as adults. In contrast, adults of the species Leptotyphlos carlae, a type of worm snake found on the island of Barbados, average only 10 cm (4 inches) long.

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